Fluid-solid interactions in upstream oil and gas applications /

Fluid-Solid Interactions in Upstream Oil and Gas Applications, Volume 78 delivers comprehensive understanding of fluid-rock interactions in oil and gas reservoirs and their impact on drilling, production, and reservoir hydrocarbon management. The book is arranged based on intervals of the oil and ga...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Otros Autores: Hussein, Ibnelwaleed A. (Editor ), Mahmoud, Mohamed (Editor )
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Amsterdam, Netherlands ; Oxford, United Kingdom ; Cambridge MA : Elsevier, [2023]
Colección:Developments in petroleum science ; v. 78.
Temas:
Hydrocarbon reservoirs.
Petroleum > Geology.
R�eservoirs d'hydrocarbures.
P�etrole > G�eologie.
Hydrocarbon reservoirs
Petroleum > Geology
Electronic books.
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Chapter 1: Introduction to reservoir fluids and rock properties; 1.1. Introduction; 1.2. Mineralogy of reservoir rocks; 1.3. Carbonate mineralogy; 1.4. Unconventional reservoirs; 1.5. Types and composition of reservoir fluids; 1.6. Rock properties; 1.7. Conclusions
  • Chapter 2: Rheology of upstream complex fluids; 2.1. Introduction; 2.2. Basics of rheology; 2.3. Rheology of reservoir fluids; 2.4. Rheological models; 2.5. Rheology of drilling fluids; 2.6. Essential rheological properties of drilling fluids; 2.7. Factors affecting mud rheology; 2.8. Rheology of emulsions; 2.9. Other applications in upstream; 2.10. Conclusions;
  • Chapter 3: Interactions of drilling and completion fluids during drilling and completion operations; 3.1. Drilling and completion fluids components; 3.2. Drilling and completion fluids stability; 3.3. Fluid/solid and solid/solid interactions in drilling and completion fluids; 3.4. Compatibility of different additives used in drilling and completion fluids; 3.5. Interaction of drilling and completion fluids solids with the formation rocks; 3.6. Interactions of drilling fluid filtrate with the formation rocks and fluids; 3.7. Concluding remarks
  • Chapter 4: Interactions of fluids during sandstone acidizing operations; 4.1. Basic chemistry of sandstone acidizing; 4.2. Composition of stimulations fluids during sandstone acidizing; 4.3. Compatibility of the stimulation fluid ingredients; 4.4. Acid/sandstone interactions during sandstone acidizing; 4.5. Adsorption and retention of stimulation fluids (ingredients) in the formation rocks; 4.6. Fines migration and clay swelling during sandstone acidizing; 4.7. Effect of corrosion inhibitors on sandstone wettability; 4.8. Modeling of sandstone acidizing; 4.9. Lumped-parameter model; 4.10. Detailed reaction models; 4.11. Conclusions
  • Chapter 5: Interactions of fluids during hydraulic and acid fracturing operations; 5.1. Introduction; 5.2. Reaction kinetics of different fracturing fluids with carbonates; 5.3. Components and compatibility of fracturing fluids properties; 5.4. Fracturing fluids and formation damage (fracture face skin); 5.5. Proppant embedment and its effect on fracture conductivity; 5.6. Fracturing fluid leak-off and filtrate interaction with the reservoir rocks and fluids; 5.7. Fracturing fluid residue clean- up; 5.8. Wettability alteration during hydraulic fracturing operations; 5.9. Environmental and social impact; 5.10. Effect of mineralogy on the interaction of acid fracture fluids with carbonates; 5.11. Interactions of spent acid with formation rocks and fluids; 5.12. Wettability alteration during acid fracturing operations; 5.13. Combined use of different acid fracturing fluids; 5.14. Experimental evidence on fracture damage
  • Chapter 6: Fluid-rock interactions in tight gas reservoirs: Wettability, pore structural alteration, and asso; 6.1. Background of tight gas reservoirs; 6.2. Wettability and pore structural alteration; 6.3. Types of flows in tight/unconventional reservoirs; 6.4. Multiphysics flow in tight/unconventional reservoirs: Incorporation of chemical damage; 6.5. Multiphysics flow in sorptive dual-porosity tight rocks; 6.6. Conclusion; Acknowledgments
  • Chapter 7: Interactions during various enhanced oil recovery operations; 7.1. Introduction; 7.2. Water injection; 7.3. Gas flooding; 7.4. Fluid-solid interactions in water-based EOR methods; 7.5. Conclusion and recommendation
  • Chapter 8: Nanoparticles in upstream applications; 8.1. Introduction; 8.2. Nanoparticles applications in drilling; 8.3. Nanoparticles in drilling fluids; 8.4. Nanoparticle in a filter cake; 8.5. Nanoparticles for formation damage during drilling; 8.6. Nanoparticle for cementing applications; 8.7. Application of nanoparticles for enhanced oil recovery; 8.8. Oil recovery using nanofluids; 8.9. Wettability alteration using nanoparticles; 8.10. Change in interfacial tension using nanoparticles; 8.11. Factors affecting nanofluid stability; 8.12. Agglomeration caused by storage time; 8.13. Agglomeration caused by salinity; 8.14. Agglomeration caused by high temperature; 8.15. Applications of nanofluids in fracturing and stimulation; 8.16. Additive in polymeric fracturing fluids; 8.17. Additive in viscoelastic surfactant fracturing fluids; 8.18. Additive in foam-based fracturing fluids; 8.19. Challenges and outlook
  • Chapter 9: Molecular simulations in upstream applications; 9.1. Introduction; 9.2. Computational chemistry and molecular simulations; 9.3. Practical details; 9.4. Enhanced oil recovery; 9.5. Enhanced gas recovery; 9.6. Estimation of ultimate recovery; 9.7. Scale removal and inhibition; 9.8. Summary; Acknowledgments
  • Chapter 10: Environmental impacts and mitigation measures of offshore oil and gas activities; 10.1. Introduction; 10.2. Offshore facilities--Central processing platform (CPP); 10.3. Environmental standards and regulations compliance requirements; 10.4. Offshore drilling and seabed dredging; 10.5. Environmental threats from offshore oil and gas operations; 10.6. Integrated health safety environment and risk management system; 10.7. Risk management approach; 10.8. Benefits of integrated HSE and risk management system; 10.9. Produced water and effluent discharge limits; 10.10. Ballast water discharge legal requirements; 10.11. Requirements highlights; 10.12. Regulation D-2: Standard (all ships must meet D-2 standards by 2024); 10.13. Biodiversity: Legal requirement, mitigation, and compensation mechanism; 10.14. HSE key performance indicators (KPIs); 10.15. Conclusions

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